KR100637974B1 - Thermally-actuated switch - Google Patents

Abstract

A thermally-actuated switch (1), comprising a switch body (2) having a metallic pressure-tight sealed container (4) and a contact mechanism installed in the air-tight sealed container (4) and a holder (3) having a base (3A) with an installation surface (3L) for an electric motor (10) to fit the motor to a coil end (11) and a holding part (3B) installed on the surface of the base opposite to the installation surface and holding the switch body (2), wherein the base is formed sufficiently large so that the switch body held on the holding part is not extended from the base, whereby a conductive heat and radiation heat from the coil end can be prevented from directly reaching the switch body when the thermally-actuated switch is fitted to the coil end. <IMAGE>

Description

Thermal Response Operation Switch {THERMALLY-ACTUATED SWITCH}

The present invention relates to a thermally responsive switch for protecting a hermetic electric compressor from overheating or dissipation.

Heat-responsive actuating switches for protecting hermetic electric compressors are divided into external attachment type and built-in type according to their installation method. Since the built-in thermal response operation switch is disposed inside the sealed container of the electric compressor, it is superior to the externally attached type in terms of the response speed to the temperature rise of the refrigerant filling the electric motor or the sealed container constituting the electric compressor. .

The built-in thermal response switch has a switch body formed by arranging an opening / closing mechanism inside a metal pressure-tight container so as not to cause property changes or poor conduction even when exposed to a refrigerant or lubricating oil for a long time in a sealed container at high pressure. It is comprised. Therefore, the heat-response actuated switch is inside the sealed container, for example, the inner surface of the sealed container or the electric compressor in a state in which the switch body (sealed container) is stored in an electrically insulating resin case or covered with an electrically insulating coating. Airtight terminals are installed at the coil end of the motor.

When the heat-responsive switch is installed on the inner surface of the sealed container or the airtight terminal of the electric compressor, it is necessary to fix the support for supporting the heat-responsive switch on the inner surface or the airtight terminal of the sealed container. In recent years, miniaturization of the electric compressor has been achieved by making the internal space of the sealed container as small as possible, and in the case of the above configuration, restrictions on the installation posture and the installation position of the heat-response actuating switch and the support are increased.

When the heat-response switch is provided on the coil end of the electric motor, the airtight container is covered with an electrically insulating coating made of a heat-shrinkable polyester sheet or the like in a tubular shape, and the coil end is tied to the coil end by a tie string such as polyester. It is tied together. The string is usually used for joining coil windings.

In the case of the above configuration, there is no need for a special component for installing the thermally responsive switch on the coil end. Moreover, a heat response actuating switch can be accommodated in the airtight container in the state integrated with the coil end.

By the way, with respect to the insulation coating which consists of polyester sheets, there exists a problem that a polyester string is slippery. Moreover, when heat-shrink a cylindrical insulating coating, there exists a problem that a part which is not in close contact with an airtight container shrinks and hardens in an amorphous form, and it is hard to hang a string.

In addition, the insulating coating has a thickness dimension of about 0.15 mm small in consideration of shrinkage and handling workability, so that heat from the coil end is quickly transmitted to the thermally responsive switch. Since it covers the whole, it prevents the heat exchange between the refrigerant | coolant in a hermetically sealed container, and a heat response operation switch. In recent years, in order to downsize the motor, a coil having a small wire diameter tends to be used, and even if it is within a normal operating current range, the amount of heat generated by the motor coil is increasing. For this reason, especially in the vicinity of the upper limit of the operating current range, there is a problem that the thermal response operation switch operates to cut off the current despite being below the operating current. In addition, there has been a problem that the thermal response operation switch is sensitive to the temporary and sudden temperature rise of the motor coil due to a short-time overload condition that does not require a protective operation.

Therefore, in order to solve the above problem, the present inventor has invented and filed a heat-response actuated switch composed of a switch main body and an electrically insulating holder supporting the switch main body (Japanese Patent Application Laid-Open No. 2001-115962). The holder has a support for accommodating or elastically supporting the switch body. The switch main body supported by the holder is tied to the coil end by a tie and fixed.

The heat-response actuated switch shown in FIG. 2 of the above application can heat exchange efficiently with the refrigerant because most of the surface of the switch body is exposed to the refrigerant. However, since it is not enough to block the radiant heat from the coil end, it also reacts sensitively to the heat generation of the coil end. In particular, when the difference between the calorific value at the time of normal operation and the calorific value at the time of abnormality is small, there is a fear that the thermal response operation switch may malfunction.

Moreover, since the switch main body is accommodated in the cylindrical part, the heat response operation switch shown in FIG. 6 of the said application had many parts which cover the switch main body, and heat exchange with the refrigerant was inadequate.

Therefore, it is an object of the present invention to provide a thermally responsive switch which does not malfunction even when installed in a hermetic electric compressor equipped with an electric motor coil having a small difference in the amount of heat generated during normal operation and a value generated during abnormality.

The present invention is a heat-response actuating switch provided in the coil end of a hermetic electric compressor provided with a motor coil, comprising: a switch body comprising a metal pressure-tight container and a contact mechanism provided inside the hermetic container, and the coil end. A base having an installation surface of the base and a holder provided on a surface of the base opposite to the installation surface, the holder having a support for supporting the switch body, wherein the base is provided with radiant heat from the coil end. It is characterized in that it is configured in a size that prevents direct impact.

According to the said structure, the conductive heat and radiant heat from the said coil end can be interrupted by the base which exists between a switch main body and a coil end. In addition, excessive temperature rise of the switch main body is prevented by the refrigerant flowing around the switch main body. Therefore, it is possible to prevent sensitive reaction to the heat generation of the coil end, and to prevent the malfunction of the coil end in a short time overload condition or the like that does not require the protection operation.

1 is a perspective view of a thermally actuated switch showing a first embodiment of the present invention.

2 is a top view of a thermally responsive switch.

3 is a view showing a state in which the heat response actuation switch is viewed from the wall side of the holder;

4 is a perspective view showing the holder in one direction.

5 is a perspective view of the holder viewed from the other inlet;

Fig. 6 is a view showing and showing the heat response actuating switch installed at the coil end from the inner circumference of the motor coil;

7 is a top view of a heat responsive actuating switch installed at the coil end.

FIG. 8 is a view corresponding to FIG. 3 of a thermally responsive switch showing a second embodiment of the present invention. FIG.

BRIEF DESCRIPTION OF DRAWINGS To describe the invention in more detail, it is described in accordance with the accompanying drawings.

First, a first embodiment of the present invention will be described with reference to FIGS. 1 to 7. 1 to 3 are views showing the overall configuration of the heat response actuation switch according to the present embodiment, FIGS. 4 and 5 are views showing a holder constituting the heat response actuation switch, and FIGS. 6 and 7 are heat response actuation switches. Is a diagram showing a state in which a coil is installed at a coil end of an electric motor.

As shown in Figs. 1 to 3, the thermal response actuating switch 1 is composed of a switch body 2 and a holder 3. The switch main body 2 is configured with a metal pressure-tight container 4 and a contact mechanism (not shown) disposed inside the gas-tight container 4. The contact mechanism is configured such that the contact is opened and closed by a heat response actuating member such as bimetal.                 

Two conductive terminals 5 protrude from one end surface of the hermetic container 4. The conductive terminal 5 penetrates through holes (not shown) provided in one end surface of the hermetic container 4. An electrically insulating filler 6 such as glass is filled between the conductive terminal 5 and the through hole, whereby the conductive terminal 5 is hermetically fixed to the hermetic container 4. The lead wires 7 are electrically fixed to the conductive terminals 5 by welding or the like, respectively.

The holder 3 is made of an electrically insulating material such as synthetic resin or ceramics. As shown in FIGS. 1-5, the said holder 3 is comprised by the base 3A of flat plate shape, and the support part 3B standing up on the upper surface which is one surface of the base 3A. The lower surface, which is the other surface of the base 3A, is the installation surface 3L.

The base 3A has a thickness dimension of about 2 mm in order to obtain sufficient strength and heat insulation. The base 3A is composed of a mounting portion 3M on which the supporting portion 3B is placed upright and on which the switch main body 2 is placed, and a tapered fixing portion 3C provided at both ends thereof. The placing portion 3M is configured sufficiently large so that the mounted switch main body 2 does not protrude. In this embodiment, the mounting portion 3M and the fixing portion 3C, that is, the entire base 3A, function as a shielding portion.

Moreover, two protrusions 3J are provided in the upper surface of the said mounting part 3M. In addition, an insertion protrusion 3K for temporarily fixing the holder 3 to the coil end 11 (both in FIGS. 6 and 7) of the electric motor 10 is provided on the lower surface of the mounting portion 3M. It is.                 

At the distal end of the fixed portion 3C, a locking portion 3D in the shape of a bevel is provided. 3 C of said fixing | fixed parts of the coil end 11 when the base 3A (holder 3) was fixed on the coil end 11 (all FIG. 6 and FIG. 7) of the electric motor 10 were carried out. It is comprised so that it may incline to one side toward the front-end | tip so that it may follow the planar shape which comprises ring shape. In particular, in the present embodiment, the inclination angles of the lower part and the upper part arranged on the inner circumferential side and the outer circumferential side of the motor coil among the fixing parts 3C are configured to be different (see FIG. 2). By such a configuration, the base 3A can be arranged with respect to various coil ends having different diameters without being protruded from the upper surface thereof.

The said support part 3B is comprised with the wall part 3N substantially perpendicular to the said base 3A, and the flange 3F provided in the upper end part and side part of the said wall part 3N. The wall portion 3N is provided with an elliptical through hole 3E through which the conductive terminal 5 is inserted. The through hole 3E is configured as large as possible in order to improve heat exchange between the refrigerant and the airtight container 4. A projection 3H extending downward is provided on the upper portion of the inner peripheral portion of the through hole 3E. Moreover, the projection part 3G of protrusion shape is provided in the both ends of the upper surface of the said flange 3F.

The switch main body 2 is fixed to the holder 3 of the above configuration as follows. That is, the conductive terminal 5 is inserted into the through hole 3E, and one end surface of the hermetic container 4 is brought into contact with the wall portion 3N. As a result, one end of the airtight container 4 is fitted into the support portion 3B. At this time, the projection 3H is disposed between the two conductive terminals 5. In addition, a space through which the refrigerant can flow is formed between the airtight container 4 and the mounting portion 3M by the protrusion 3J.

Subsequently, the lead wire 7 is fixed to the conductive terminal 5 of the switch main body 2 set in the holder 3. As a result, one end surface of the airtight container 4 is relatively strongly in contact with the wall portion 3N by the lead wire 7, and the switch main body 2 is fixed to the holder 3. In this state, the switch main body 2 is not completely fixed with respect to the holder 3, but at the time of installation of the heat-response actuating switch 1 with respect to the coil end 11 described later, the switch main body 2 is connected to the holder ( Falling off from 3) is sufficiently prevented. In addition, the protrusion 3H is surrounded by the conductive terminal 5, the airtight container 4, and the lead wire 7 by the configuration in which the protrusion 3H is positioned between the conductive terminals 5. For this reason, the switch main body 2 is supported in the state positioned with respect to the holder 3.

By the way, it is also conceivable that the holder 3 is made of an elastic material and the holder 3 is configured to elastically support the switch main body 2. However, when the holder 3 also needs heat resistance and refrigerant resistance, and elasticity is required, the width of the material selection of the holder 3 becomes narrower. On the other hand, in the present embodiment, the holder 3 does not need to have elasticity by adopting the above configuration, which increases the degree of freedom in material selection.

Next, the installation operation of the heat response actuating switch 1 with respect to the coil end 11 is demonstrated, referring FIG. 6 and FIG. First, the heat response actuating switch 1 is disposed on the coil end 11 such that the installation surface 3L of the base 3A contacts the upper surface of the coil end 11 of the electric motor 10. At this time, the insertion protrusion 3K is inserted between the windings of the coil end 11, whereby the thermal response actuating switch 1 is temporarily fixed to the coil end 11.                 

The heat response actuating switch 1 temporarily fixed on the coil end 11 is fixed by a tie string 12 such as polyester. At this time, the string 12 caught by the heat response actuating switch 1 is prevented from being peeled off from the holder 3 by the locking portions 3D and 3G.

In this way, the base 3A is located between the switch main body 2 and the coil end 11 in the heat response actuating switch 1 fixed on the coil end 11. In addition, the base 3A has a size that shields the radiant heat from the coil end 11 so that the switch main body 2 disposed on the upper surface thereof does not protrude. For this reason, the conduction heat and the radiant heat from the coil end 11 can be largely prevented from directly being transmitted to the switch main body 2.

In addition, since the base 3A has a flat plate shape and the portion covering the switch body is made very small, heat exchange with the refrigerant can be facilitated while shielding the radiant heat from the coil end 11.

In addition, the through hole 3E was made as large as possible so that the switch main body 2 and the refrigerant were easily in contact with each other. Moreover, the protrusion 3J was provided in the upper surface of 3M of mounting parts, and the space which the refrigerant | coolant can distribute | circulate between the airtight container 4 and the base 3A was ensured. For this reason, heat exchange between the hermetic container 4 and the refrigerant is performed efficiently, and the heat response actuating switch 1 can operate quickly with respect to the temperature change of the refrigerant.

Moreover, since the thickness dimension of the holder 3 was enlarged and the space was secured between the coil end 11 and the base 3A, the heat of the coil end 11 passes through the base 3A, and the switch main body ( It becomes hard to be delivered to 2). For this reason, although the heat generation of the coil end 11 to the extent that the refrigerant is not overheated, for example, due to the short-time overload state that does not require heat generation or protection of the coil end 11 during normal operation, In addition, the switch main body 2 does not operate sensitively by a sudden temperature rise.

In addition, the base 3A was configured to conform to the planar shape of the coil end 11, and the heat response actuating switch 1 was configured not to protrude from the base 3A. For this reason, the heat response actuation switch 1 does not protrude from the coil end 11 and interfere with the sealed container of the compressor.

Fig. 8 shows a second embodiment of the present invention and explains the differences from the first embodiment. In addition, the same code | symbol is attached | subjected to the same part as 1st Example. That is, the heat response actuating switch 21 of the present embodiment forms two through holes 23E in the supporting portion 3B of the holder 3. The through hole 23E is formed corresponding to the positions of the two conductive terminals 5 included in the switch main body 2.

By forming two through holes 23E in this manner, the intermediate portion 23H located between the through holes 23E is surrounded by the conductive terminal 5, the airtight container 4, and the lead wires 7. Thus, as in the first embodiment, the switch main body 2 is reliably positioned and supported with respect to the holder 3.

In the present embodiment, the spacer 23L as raised is provided on the mounting surface 3L of the base 3C. The spacer 23L is provided in the lower portion of the engaging portions 3D and 3G in the installation surface 3L in consideration of the force applied when the string 12 that is tied to the thermal response switch 21 is fixed by being fixed. have. When the heat response actuation switch 21 is placed on the coil end 11 by the spacer 23L, a gap in which the refrigerant can flow is formed between the coil end 11 and the base 3A. Therefore, since the contact area of the base 3A and the coil end 11 becomes small, it becomes difficult to transfer the heat of the coil end 11 to the switch main body 2 through the base 3A further.

In addition, this invention is not limited to the above-mentioned embodiment, For example, the following modifications are possible.

The base 3A should just have a thickness dimension of 1 mm or more. By such a configuration, sufficient strength and heat insulation can be obtained.

Instead of providing the locking portions 3D and 3G, the upper surface of the supporting portion 3B or the fixing portion 3C may be in the form of a wave surface, whereby the string 12 to be bundled may be prevented from being peeled off from the holder 3.

The number of conductive terminals is not limited to two, but may be three or more. In addition, the metal container itself may be used as a conductive terminal.

As described above, the heat responsive switch according to the present invention is installed at the coil end of the electric motor constituting the hermetic electric compressor, and is useful as an apparatus for protecting the electric motor from overheating or disappearing, and particularly at normal temperature and abnormal condition. It is suitable for use with a motor coil having a small temperature difference.

Claims (9)

A heat responsive actuating switch provided at said coil end of a hermetic electric compressor provided with an electric motor coil, A switch body comprising a metal pressure-resistant hermetic container and a contact mechanism provided inside the hermetic container; A base having an installation surface on the coil end and a holder provided on a surface of the base opposite to the installation surface, and having a support for supporting the switch body; The base is configured to have a size such that the switch body does not protrude so as to prevent direct radiant heat from the coil end directly affecting the switch body, The switch main body has a conductive terminal through which the lead wire is connected by hermetically penetrating the hermetic container, and the holder has a through hole through which the conductive terminal is inserted, And the holder is held by the hermetic container and the lead wire by connecting the lead wire to the conductive terminal inserted into the through hole. delete The method of claim 1, The holder is provided on the periphery of the through hole and provided with a protrusion projecting in the through hole, And the projection is sandwiched by the hermetic container and the lead wire. The method of claim 3, wherein The switch body has at least two conductive terminals, And said projection is provided so as to be located between said conductive terminals. The method of claim 1, The switch body has a plurality of conductive terminals, The holder has a plurality of through holes corresponding to each of the conductive terminals, And the holder is held by the hermetic container and the lead wire by connecting the lead wire to each of the conductive terminals inserted into the through hole. The method of claim 1, And a ridge forming a gap in which the refrigerant can flow between the mounting surface and the coil end when the holder is installed on the coil end. The method of claim 1, And the base has a planar shape. A heat responsive actuating switch provided at said coil end of a hermetic electric compressor provided with an electric motor coil, A switch body comprising a metal pressure-resistant hermetic container and a contact mechanism provided inside the hermetic container; A base having an installation surface on the coil end and a holder on the side opposite to the installation surface of the base, the holder having a support for supporting the switch body, The base acts as a shield to shield radiant heat from the coil end toward the switch body, The switch main body has a conductive terminal through which the lead wire is connected by hermetically penetrating the hermetic container, and the holder has a through hole through which the conductive terminal is inserted, And the holder is held by the hermetic container and the lead wire by connecting the lead wire to the conductive terminal inserted into the through hole. The method of claim 8, And the base has a planar shape.

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